生物反应器培养BHK-21悬浮细胞增殖伪狂犬病病毒工艺优化

doi:10.11843/j.issn.0366-6964.2022.11.019

畜牧兽医学报 ›› 2022, Vol. 53 ›› Issue (11): 3936-3947.doi: 10.11843/j.issn.0366-6964.2022.11.019

生物反应器培养BHK-21悬浮细胞增殖伪狂犬病病毒工艺优化

王家敏^1,2, 李自良^1,3, 马芳芳^1,3, 康碧静^1,3, 田玲^1,3, 李倬³, 马忠仁^1,2, 乔自林^1,2*

1. 西北民族大学生物医学研究中心甘肃省动物细胞技术创新中心, 兰州 730030;
2. 四川大学生物治疗国家重点实验室, 成都 610041;
3. 西北民族大学生命科学与工程学院, 兰州 730030

收稿日期:2022-04-19 出版日期:2022-11-23 发布日期:2022-11-25
通讯作者: 乔自林,主要从事动物细胞生物反应器大规模培养技术研究,E-mail:qiaozilin@xbmu.edu.cn
作者简介:王家敏(1987-),女,山东诸城人,讲师,博士生,主要从事细胞工程(疫苗方向)研究,E-mail:jiaminwang1987@163.com,Tel:0931-2938313;李自良(1992-),甘肃临夏人,硕士,主要从事细胞培养、生物制品的研发等研究,E-mail:1336797104@qq.com
基金资助:
西北民族大学中央高校基本科研业务费专项资金项目（31920210053）；教育部动物医学生物工程创新团队（IRT_17R88）

Optimization of BHK-21 Suspension Cells to Propagate Pseudorabies Virus in Bioreactor

WANG Jiamin^1,2, LI Ziliang^1,3, MA Fangfang^1,3, KANG Bijing^1,3, TIAN Ling^1,3, LI Zhuo³, MA Zhongren^1,2, QIAO Zilin^1,2*

1. Gansu Tech Innovation Center of Animal Cell, Biomedical Research Center, Northwest Minzu University, Lanzhou 730030, China;
2. The State Key Laboratory of Biotherapy and Cancer Center, Sichuan University, Chengdu 610041, China;
3. College of Life Science and Engineering, Northwest Minzu University, Lanzhou 730030, China

Received:2022-04-19 Online:2022-11-23 Published:2022-11-25

摘要/Abstract

摘要： 旨在筛选伪狂犬病病毒（PRV）敏感的BHK-21细胞并分析其生长和病毒增殖特性，优化反应器中BHK-21悬浮细胞的培养和病毒增殖条件，建立生物反应器培养BHK-21悬浮细胞增殖PRV工艺。本研究利用响应面和单因素优化法，以细胞生长动力学特性、TCID₅₀病毒滴度等参数为指标，优化1.2 L生物反应器中BHK-21悬浮细胞的最佳培养和增殖病毒条件，在5 L生物反应器中进一步批培养验证。结果显示，筛选获得PRV高敏感的BHK-21-02贴壁细胞和BHK-21-XF02悬浮细胞各1株，BHK-21-XF02悬浮细胞在含3%血清的SLM-BHK低血清培养基和SFM-BHK无血清培养基中均能实现良好的生长和病毒增殖。利用响应面法优化得到1.2 L反应器最佳培养条件为接种密度1.20×10⁶cells·mL^-1、搅拌转速120 r·min^-1、DO值40%，5 L反应器批培养72 h细胞密度可达（7.61±0.18）×10⁶ cells·mL^-1、细胞活率为（96.93±1.18）%。利用单因素法优化得到1.2 L反应器最佳病毒增殖条件为MOI 0.001、培养温度37℃、细胞密度2.0×10⁶cells·mL^-1、搅拌转速80 r·min^-1，5 L反应器批培养接毒后48 h病毒滴度达到最大值（7.13±0.11） lgTCID₅₀·mL^-1。本研究可为PRV疫苗相关研究和规模化生产提供参考。

关键词: BHK-21悬浮细胞, 生物反应器, 伪狂犬病病毒, 敏感性

Abstract: In this study, we screened the BHK-21 cells which were sensitive to pseudorabies (PRV) and analyzed their growth and virus production characteristics. The conditions of cell culture and virus production in the reactor were optimized, so we finally established the PRV propagation process of BHK-21 suspension cells in bioreactor. The optimal culture and virus propagation conditions of BHK-21 suspension cells in 1.2 L bioreactor based on cell growth dynamics and TCID₅₀ virus titer, were optimized by response surface methodology and single factor optimization method, and further batch culture was carried out in 5 L bioreactor. The results showed that one of adherent cells named BHK-21-02 and one of suspension cells named BHK-21-XF02 with high PRV sensitivity were screened. BHK-21-XF02 suspension cells could achieve good growth and virus propagation in serum-low medium containing 3% serum and serum-free medium. Using response surface methodology, the optimum cell culture conditions of 1.2 L reactor were as follows:inoculation density was 1.20×10⁶ cells·mL^-1, stirring speed was 120 r·min^-1 and DO was 40%, the cell density could reach (7.61±0.18)×10⁶ cells·mL^-1 and the cell viability was (96.93±1.18)% after batch culture in 5 L reactor for 72 hours. Using single factor method, the optimal conditions of virus propagation in 1.2 L reactor were as follows:MOI was 0.001, temperature was 37℃, cell density for virus inoculation was 2.0×10⁶cells·mL^-1 and stirring speed was 80 r·min^-1. Under conditions, the virus titer reached (7.13±0.11) lgTCID₅₀·mL^-1 at 48 hours in 5 L reactor batch culture. Furthermore, all process steps can be fully scaled up to industrial quantities for commercial manufacturing of PRV vaccines.

Key words: BHK-21 suspension cell, bioreactor, pseudorabies virus, susceptibility

中图分类号:

S852.659.1

王家敏, 李自良, 马芳芳, 康碧静, 田玲, 李倬, 马忠仁, 乔自林. 生物反应器培养BHK-21悬浮细胞增殖伪狂犬病病毒工艺优化[J]. 畜牧兽医学报, 2022, 53(11): 3936-3947.

WANG Jiamin, LI Ziliang, MA Fangfang, KANG Bijing, TIAN Ling, LI Zhuo, MA Zhongren, QIAO Zilin. Optimization of BHK-21 Suspension Cells to Propagate Pseudorabies Virus in Bioreactor[J]. Acta Veterinaria et Zootechnica Sinica, 2022, 53(11): 3936-3947.

参考文献 24

[1]	TAN L, YAO J, YANG Y D, et al.Current status and challenge of pseudorabies virus infection in China[J].Virol Sin, 2021, 36(4):588-607.
[2]	WANG G S, DU Y J, WU J Q, et al.Vaccine resistant pseudorabies virus causes mink infection in China[J].BMC Vet Res, 2018, 14(1):20.
[3]	LIAN K Q, ZHANG M L, ZHOU L L, et al.First report of a pseudorabies-virus-infected wolf (Canis lupus) in China[J].Arch Virol, 2019, 165(2):459-462.
[4]	BO Z Y, MIAO Y R, XI R, et al.Emergence of a Novel pathogenic recombinant virus from Bartha vaccine and variant pseudorabies virus in China[J].Transbound Emerg Dis, 2021, 68(3):1454-1464.
[5]	AI J W, WENG S S, CHENG Q, et al.Human endophthalmitis caused by pseudorabies virus infection, China, 2017[J].Emerg Infect Dis, 2018, 24(6):1087-1090.
[6]	ZHANG T, LIU Y C, CHEN Y M, et al.A single dose glycoprotein D-based subunit vaccine against pseudorabies virus infection[J].Vaccine, 2020, 38(39):6153-6161.
[7]	ZHOU J Z, LI S, WANG X B, et al.Bartha-k61 vaccine protects growing pigs against challenge with an emerging variant pseudorabies virus[J].Vaccine, 2017, 35(8):1161-1166.
[8]	LIU Y M, CHEN Q H, RAO X D, et al.An economic assessment of pseudorabies (Aujeszky' disease) elimination on hog farms in China[J].Prev Vet Med, 2019, 163:24-30.
[9]	LIANG C, TONG W, ZHENG H, et al.A high-temperature passaging attenuated pseudorabies vaccine protects piglets completely against emerging PRV variant[J].Res Vet Sci, 2017, 112:109-115.
[10]	PETIOT E, PROUST A, TRAVERSIER A, et al.Influenza viruses production:evaluation of a novel avian cell line DuckCelt®-T17[J].Vaccine, 2018, 36(22):3101-3111.
[11]	DILL V, HOFFMANN B, ZIMMER A, et al.Influence of cell type and cell culture media on the propagation of foot-and-mouth disease virus with regard to vaccine quality[J].Virol J, 2018, 15(1):46.
[12]	BISSINGER T, WU Y X, MARICHAL G P, et al.Towards integrated production of an influenza A vaccine candidate with MDCK suspension cells[J].Biotechnol Bioeng, 2021, 118(10):3996-4013.
[13]	ISKANDAR V I, SASAKI Y, YOSHINO N, et al.Optimization of trypsins for influenza A/H1 N1 virus replication in MDCK SI-6 cells, a novel MDCK cell line[J].J Virol Methods, 2018, 252:94-99.
[14]	BISSINGER T, FRITSCH J, MIHUT A, et al.Semi-perfusion cultures of suspension MDCK cells enable high cell concentrations and efficient influenza A virus production[J].Vaccine, 2019, 37(47):7003-7010.
[15]	NÚÑEZ E G F, LEME J, DE ALMEIDA PARIZOTTO L, et al.Influence of aeration-homogenization system in stirred tank bioreactors, dissolved oxygen concentration and pH control mode on BHK-21 cell growth and metabolism[J].Cytotechnology, 2014, 66(4):605-617.
[16]	SRČEK V G, ČAJAVEC S, SLADIĆ D, et al.BHK 21 C13 cells for Aujeszky's disease virus production using the multiple harvest process[J].Cytotechnology, 2004, 45:101-106.
[17]	CHUNG S, TIAN J, TAN Z J, et al.Modulating cell culture oxidative stress reduces protein glycation and acidic charge variant formation[J].MAbs, 2019, 11(1):205-216.
[18]	WANG D, TAO X G, FEI M M, et al.Human encephalitis caused by pseudorabies virus infection:a case report[J].J NeuroVirol, 2020, 26(3):442-448.
[19]	HIPPACH M B, SCHWARTZ I, PEI J, et al.Fluctuations in dissolved oxygen concentration during a CHO cell culture process affects monoclonal antibody productivity and the sulfhydryl-drug conjugation process[J].Biotechnol Prog, 2018, 34(6):1427-1437.
[20]	NIE J Q, SUN Y, PENG F, et al.Production process development of pseudorabies virus vaccine by using a novel scale-down model of a fixed-bed bioreactor[J].J Pharm Sci, 2020, 109(2):959-965.
[21]	NIE J Q, SUN Y, PENG F, et al.Production process development of pseudorabies virus vaccine by using a novel scale-down model of a fixed-bed bioreactor[J].J Pharm Sci, 2020, 109(2):959-965.
[22]	DECARLI M C, DOS SANTOS D P, ASTRAY R M, et al.DROSOPHILA S2 cell culture in a WAVE Bioreactor:potential for scaling up the production of the recombinant rabies virus glycoprotein[J].Appl Microbiol Biotechnol, 2018, 102(11):4773-4783.
[23]	ROUROU S, BEN ZAKKOUR M, KALLEL H.Adaptation of Vero cells to suspension growth for rabies virus production in different serum free media[J].Vaccine, 2019, 37(47):6987-6995.
[24]	AHMED S, CHAUHAN V M, GHAEMMAGHAMI A M, et al.New generation of bioreactors that advance extracellular matrix modelling and tissue engineering[J].Biotechnol Lett, 2019, 41(1):1-25.

生物反应器培养BHK-21悬浮细胞增殖伪狂犬病病毒工艺优化

Optimization of BHK-21 Suspension Cells to Propagate Pseudorabies Virus in Bioreactor

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